A system and method for isolating and analyzing single cells, wherein the system includes: an array of wells defined at a substrate, each well including an open surface and a well cavity configured to capture cells in one of a single-cell format and single-cluster format, and a fluid delivery module including a fluid reservoir through which fluid flow is controlled along a fluid path; and wherein the method includes: capturing a population of particles into the array of wells in single-particle format; releasing, from the particles, a set of probes into the array of wells; capturing a population of cells into the array of wells in single-cell format; releasing biomolecules from each captured cell into the array of wells; and generating a set of genetic complexes comprising the biomolecules associated with a single captured cell and a subset of probes within individual wells of the array of wells.

A system for buoyant particle processing includes: a reaction vessel, a stirring mechanism, a set of one or more pumps, and a filter. The system can additionally or alternatively include a set of pathways and/or any other suitable component(s). A method for buoyant particle processing includes: stirring the contents of a reaction vessel; washing a set of buoyant particles; and filtering the contents of the reaction vessel. Additionally or alternatively, the method can include any or all of: preprocessing the set of buoyant particles; adding a set of inputs to the reaction vessel; washing the set of buoyant particles; repeating one or more; and/or any other suitable process(es).

An adherent cell culture substrate, which is a sheet-shaped substrate used for producing a culture vessel for adherent cells, includes a groove including a crest-shaped portion and a valley-shaped portion on one surface side of the substrate, in which a distance from a top end portion of the crest-shaped portion to the other surface of the substrate is 1 mm or less. Further, it is preferable that a cross section of the groove perpendicular to a direction in which the groove extends is formed in a substantially V-shape and an inclination angle of a side surface of the substantially V-shape of the groove is 80 degrees or less. Further, it is preferable that a plurality of the grooves are linearly arranged in parallel and the top end portions of the crest-shaped portions are formed in a linear shape.

An extra-capillary fluid cycling unit for maintaining and cycling fluid volumes in a cell culture chamber includes a housing and a first flexible reservoir extra-capillary fluid reservoir disposed in the housing. The extra-capillary fluid reservoir is in fluid communication with a cell culture chamber. A second flexible reservoir is also located in the housing, the second flexible reservoir being in fluid communication with a pressure source. A sensor plate is movably disposed in the housing between the extra-capillary reservoir and the second reservoir, wherein the second reservoir is pressurized to move the sensor plate in relation to the extra-capillary reservoir to cause fluid cycling and maintain fluid volumes in the cell growth chamber.

The methods of the invention employ targeted magnetic particles, preferably targeted nanomagnetic particles, and targeted buoyant particles such as buoyant microparticles and microbubbles. Among the benefits of the invention is the ability to combine targeted magnetic particles with differentially targeted buoyant particles to achieve separation of two or more specifically cell targeted populations during the same work flow.

A filtration and collection device capable of improving the collection rate of filtration targets. The filtration and collection device may include a holder having an inlet port for pouring a liquid, a discharge port for discharging the liquid, a flow path through which the inlet port and the discharge port communicate, and a groove portion formed on an outer periphery of the holder, a filter disposed in the flow path of the holder and having a plurality of through-holes, and one or a plurality of grip sections having an insertion portion that is inserted into the groove portion, in which a gap is formed between the groove portion and the insertion portion.

The present disclosure relates to a method of colony picking. The method includes the steps of mixing a bacterial suspension with an oil-based carrier liquid for generating a plurality of droplets comprising bacteria contained in the bacterial suspension and incubating the plurality of droplets for a predetermined period of time to allow growth of bacteria within the plurality of droplets. The method further includes the steps of screening each of the plurality of droplets that flows through one or more microfluidic channels of a microfluidic device to determine an opacity degree of each of the plurality of droplets, wherein the opacity degree is indicative of colony formation in the plurality of droplets, and sorting the plurality of droplets based on the opacity degree of each of the plurality of droplets.

A microfluidic particle sorting apparatus for capturing targets from fluid containing the targets is disclosed. The apparatus includes an inlet for receiving the fluid; a sorting chamber allowing the fluid to flow through; a first outlet for discharging the fluid after flowing through the sorting chamber; a capturing structure for capturing the cells, wherein the capturing structure is upstream of the first outlet, and includes obstacles in an array, each extending through the sorting chamber in a lateral direction with respect to a fluid flow of the fluid; and a second outlet upstream of the capturing structure comprising a plurality of openings; wherein a gap between two adjacent obstacles is equal to or greater than each opening of the second outlet.

A system and method for isolating and analyzing single cells, including: a substrate having a broad surface; a set of wells defined at the broad surface of the substrate, and a set of channels, defined by the wall, that fluidly couple each well to at least one adjacent well in the set of wells; and fluid delivery module defining an inlet and comprising a plate, removably coupled to the substrate, the plate defining a recessed region fluidly connected to the inlet and facing the broad surface of the substrate, the fluid delivery module comprising a cell capture mode.

Provided are a cell sorting chip, device, and method based on dielectrophoresis induced deterministic lateral displacement, the chip including a microfluidic channel (4), the microfluidic channel comprising a sample inlet (4.1), a straight channel, and two sample outlets; three groups of electrode array pairs are integrated at a bottom of the straight channel, the three electrode array pairs respectively being a focusing electrode group (1), a sorting electrode group (2), and a separating electrode group (3); the focusing electrode group is used for cell focusing and signal detection; the sorting electrode group is used for single cell sorting; and the separating electrode group is used for single cell separation. High-speed, precise, and lossless target cell sorting can thus be implemented.